A multi-deck screening assembly includes a plurality of vertically-stacked downwardly-sloping screen decks, each with grading apertures through which under-sized material may pass, while over-sized material passes over a lower discharge end of each screen deck. The screen decks are mounted on a common frame, which is mounted on a chassis and provided with vibration device. The screen decks include an upper deck, an intermediate deck below for receiving under-sized material from the upper deck, and a lower deck below the intermediate deck for receiving under-sized material from the intermediate screen deck. A first chassis-mounted stockpile conveyor receives over-sized material from the lower deck, a second chassis-mounted stockpile conveyor receives over-sized material from the intermediate deck, and a third stockpile conveyor receives over-sized material from the upper deck. A transfer conveyor is operable to deliver over-sized material from the discharge end of the upper deck onto the third stockpile conveyor.

A device for classifying a material mixture of multiple materials has a first transport unit into which the material mixture to be classified is deposited by a supply device. A second transport unit is arranged downstream. A first chute is provided between the first and second transport, via which a first material with a first fluid resistance can be separated from the material mixture. At least one third transport unit is arranged downstream of the second transport unit, such that a transit route for the materials is formed between the second and third transport units. A second chute is provided between the second and third transport units, via which at least the second material with a second fluid resistance can be separated from the material mixture. The third transport unit is designed so that material can pass through and/or a fluid flow can pass through.

A device for classifying a material mixture of multiple materials has a first transport unit into which the material mixture to be classified is deposited by a supply device. A second transport unit is arranged downstream. A first chute is provided between the first and second transport, via which a first material with a first fluid resistance can be separated from the material mixture. At least one third transport unit is arranged downstream of the second transport unit, such that a transit route for the materials is formed between the second and third transport units. A second chute is provided between the second and third transport units, via which at least the second material with a second fluid resistance can be separated from the material mixture. The third transport unit is designed so that material can pass through and/or a fluid flow can pass through.

An apparatus for separating usable crop from intermixed debris. The apparatus has: a) a conveying system configured to convey usable crop in a processing path from an upstream input location to a downstream output location; and b) a first separating system configured to cause separation of debris intermixed with usable crop as usable crop is conveyed in the processing path. A vacuum system downstream of the preliminary separating system is configured to: a) generate a low pressure volume which causes additional debris intermixed with usable crop to be drawn away from usable crop by vacuum; and b) cause drawn debris to be directed towards a collection location spaced from the output location while allowing usable crop to advance toward the output location.

An apparatus for separating usable crop from intermixed debris. The apparatus has: a) a conveying system configured to convey usable crop in a processing path from an upstream input location to a downstream output location; and b) a first separating system configured to cause separation of debris intermixed with usable crop as usable crop is conveyed in the processing path. A vacuum system downstream of the preliminary separating system is configured to: a) generate a low pressure volume which causes additional debris intermixed with usable crop to be drawn away from usable crop by vacuum; and b) cause drawn debris to be directed towards a collection location spaced from the output location while allowing usable crop to advance toward the output location.

The invention relates to a device and a method for separating and/or recovering silicate particles from plant material. This device and the method are characterized by an air classifier (3, 14), which has at least one material inlet (4), an air inlet (6), arranged under the material inlet (4), an air outlet (7) and at least one particle receptacle (8), arranged under the air outlet, wherein the plant particles recovered from plant material by crushing can be subjected to an air stream in the air classifier (3, 14) in such a way that silicate particles contained in the plant material are removed by the air stream via the air outlet (7) and, as a result of gravitational force, the plant particles are received by the particle receptacle (8) arranged under the air outlet (7) and taken away.

The invention relates to a device and a method for separating and/or recovering silicate particles from plant material. This device and the method are characterized by an air classifier (3, 14), which has at least one material inlet (4), an air inlet (6), arranged under the material inlet (4), an air outlet (7) and at least one particle receptacle (8), arranged under the air outlet, wherein the plant particles recovered from plant material by crushing can be subjected to an air stream in the air classifier (3, 14) in such a way that silicate particles contained in the plant material are removed by the air stream via the air outlet (7) and, as a result of gravitational force, the plant particles are received by the particle receptacle (8) arranged under the air outlet (7) and taken away.

A screening apparatus is disclosed. The screening apparatus includes a support; at least two screen decks arranged one over the other as an assembly, each screen deck including a screen frame, a screen and a chamber underlaying the screen surface, an outlet duct for oversized material and an outlet duct for undersized material that is in communication with the chamber; mountings configured for mounting of the assembly of the at least two screen decks to the support; and a feed unit configured to feed the material to be screened to each screen deck. The feed unit includes at least one distributor having one distributor inlet and at least two distributor outlets, which at least two distributor outlets are arranged to feed one screen deck each.

A screening apparatus is disclosed. The screening apparatus includes a support; at least two screen decks arranged one over the other as an assembly, each screen deck including a screen frame, a screen and a chamber underlaying the screen surface, an outlet duct for oversized material and an outlet duct for undersized material that is in communication with the chamber; mountings configured for mounting of the assembly of the at least two screen decks to the support; and a feed unit configured to feed the material to be screened to each screen deck. The feed unit includes at least one distributor having one distributor inlet and at least two distributor outlets, which at least two distributor outlets are arranged to feed one screen deck each.

The present invention comprises: a separation silo, a discharge silo, a upper sidewall of the separation silo communicated with the discharge silo through a communication port, wherein an air curtain is disposed in the communication port to isolate the silos from each other, a discharge port is disposed at the bottom of the discharge silo, a suction outlet is mounted on the top of the separation silo, a feeding port is disposed at the lower part of a sidewall of the separation silo, which is precisely facing towards the underside of the end of the belt conveyer, a vibration trough is arranged at the lower part of the separation silo, a damper plate is disposed underside thereof, an air inlet is located underbelly thereof at the bottom of the separation silo, a rejection outlet is installed at the underside end of the vibrating trough.